ES2354315A1 - Procedure for control of rolling devices for sending ways. (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Control procedure of rolling devices for boarding bridges formed by two units of translation, comprising: reception of the displacement setpoint defined by the gateway operator (zp), determination of the instantaneous position of the gangway; determination of the actual orientation of each translation unit with respect to its ideal orientation (wa, wb) and comparison with a limit phase angle (w); if the actual orientation of any of the translation units with respect to their ideal orientation (wa, wb) is greater than the limit offset (w), the speed to be transmitted to each wheel is determined to position each translation unit in the appropriate orientation for start the progress of the catwalk; if the actual orientation of any of the translation units with respect to their ideal orientation (wa, wb) is greater than the limit offset (w), the speed to be transmitted to each wheel is determined in order to perform the displacement of the gateway. (Machine-translation by Google Translate, not legally binding)

Description

Device control procedure rolling for boarding bridges.

Field of application of the invention

The present invention relates to a control procedure for the rolling device of gateways such as those commonly used in airports for the boarding and disembarking passengers of the plane when this system of Rolling consists of two translation units. He control procedure object of the present invention allows improve the maneuverability of the catwalk, controlling precise your position at every moment and performing a smooth maneuver and continues, reduce the time spent on docking and undocking of the gangway, since the treadmill of the gangway adapts to the ideal and shorter path in any situation, In addition to eliminating the sliding and wear of the wheels.

State of the art

The need to make the connection between the airport terminal and aircraft was presented during the first half of the twentieth century, with the appearance of the first commercial airlines The design of boarding gateways has underwent changes over time and improvements have been made technology that respond to new customer expectations and that have been rooted and extended in new designs.

The currently known gateways are formed by a structure, rotating called "roundabout" connected to the facade of the terminal where the boarding and disembarkation of passengers; a support structure of the roundabout called "column"; a "tunnel" composed of a telescopic structure that allows you to modify the length of the gateway according to the distance between the terminal and the door boarding the plane; a "lifting system" also composed by a telescopic structure on which the tunnel rests and that allows to modify its height and adapt to the level of the door of the airplane; a "rolling system" on which the lifting system and allowing the movement of the catwalk on the airport platform; a rotating structure called "cabin" that serves as a link between the gateway and the airplane; a circular structure called "round" on which turn the cabin; a "ladder" usually located in the end of the runway closest to the plane that allows access to the gateway from the airport platform.

During the docking or undocking maneuver airplane the gangway is driven by the rolling running system around the. axis of the roundabout and extending or retracting the telescopic tunnel structure.

Traditional rolling devices used on aircraft boarding gateways consist of a single translation unit connected to the lifting system with a articulated connection that allows the oscillation of the tunnel. This articulated connection is necessary to allow lifting and Descent of the gateway tunnel when the translation unit It is turned and allows to absorb possible unevenness of the platform from the airport, but it causes great instability of all the gateway especially important when the gateway serves to large airplanes, whose access doors are located at heights higher than usual, operates in conditions adverse weather conditions, or withstand large loads.

On some occasions, to provide the catwalk of greater stability, the rolling device is formed by Two independent translation units.

There are some devices on the market rolling with two translation units that improve stability of the catwalk assembly but make it difficult to maneuver the catwalk and cause greater wear of the wheels.

European patent EP 0803435 deals with a runway rolling device in which during the maneuver from the walkway it is necessary to turn around the axis of the roundabout, stop, orient the translation units according to the direction adequate and then extend or retract the structure telescopic tunnel, so it does not allow you to perform Simultaneously the turning movement around the axis of the roundabout and extension or retraction of the telescopic tunnel structure. In addition, in application EP 0803435 the sequence of operations must be done as many times as necessary, which causes greater maneuver times and greatly reduces position control of the gangway during the docking or undocking maneuver airplane.

In the Spanish patent of publication number ES2237343 the proposed device allows to perform the maneuver simultaneous extension of the telescopic structure of the tunnel of the catwalk and its turn around the roundabout, but they keep both parallel translation units along the entire path, synchronizing its position through mechanical means. In these conditions, wear and slip suffered by the wheels is greater than the one that appears when the rolling device is formed by a single translation unit, which reduces control on the maneuver of the catwalk, it causes aging premature of the wheels and transmits to the structure efforts not desired The greater the separation between the units of translation, the greater the stability of the gateway, but the greater is also this negative effect on the rolling system.

They are also known in the state of the art some gateways where the rolling device only performs a rotational movement around the axis of the roundabout and the distance between it and the roundabout axis remains constant for all the maneuver of the catwalk, in these catwalks, called radial, the problem indicated above is solved when the units of translation are not parallel, but keep a certain angle defined as a function of the distance between the device rolling, the axis of the roundabout and the separation between the units of translation. But this solution is not applicable to gateways. where the rolling device also performs the extension or retraction of the telescopic tunnel structure.

There are other rolling devices with two translation units, as disclosed in WO application 2007/048302, which control the speed of one of the four wheels (master wheel), to which the speed setpoint is sent necessary to follow the path defined by the operator. In master wheel speed function, defined path by the operator, and the position of each of the units of translation regarding the direction of this path, the PLC Calculate the speed of the other three wheels (slave wheels). This four-wheel speed difference defines different orientations of each of the translation units. This control procedure does not take into account the extension of the gangway and the angle saved by the translation units is independent of this value, so the problems of Wheel slip and wear are not resolved correctly for all catwalk positions during the maneuver of docking.

There are other control procedures such as shows US Patent 5,855,035 where an angle is defined of lag between the orientations of each of the units of translation. This offset angle is described according to the trajectory defined by the operator, the position of each of the translation units with respect to the direction of this trajectory and the length of the catwalk, but it maintains the same speed in each one of the four wheels, so they can also appear wheel slip and wear problems in some gangway positions during the docking maneuver.

Description of the invention

A boarding pass whose system of rolling consists of two translation units requires a synchronization system that coordinates the movement of both units.

The control procedure subject to the The present invention independently defines the speed of each wheel This four wheel speed difference define at each moment the most appropriate orientation of each of translation units using, among other variables, the trajectory direction defined by the operator, the position of each of the translation units with respect to the address of this path and the length of the catwalk at each moment of the maneuver.

This system allows you to move the gateway from smoothly and continuously controlling your position at every moment and eliminating problems of wear and wheel slip observed in other executions in any position of the catwalk during the docking maneuver.

The present invention consists of a runway control device for runways boarding consisting of two transfer units that understands:

a) receipt of the travel setpoint defined by the gateway operator,

b) precise position determination snapshot of the gateway and its features through the uptake of all the necessary variables for this: position of the elevation relative to the axis of the round, distance between the axis of round and the axis of roundabout at each instant or the length of the runway measured from the center of the roundabout to the end of the cabin, position of each of the translation units with respect to to the axis of the gangway, position of the wheels in each of the translation units with respect to the point of attachment to the structure of the elevation and diameter of each of the wheels,

c) determination of the calculation parameters: position of the instantaneous center of rotation relative to the center of the roundabout, instant turning radii of each of the units of translation, ideal orientations with respect to the axis of the catwalk and ideal speeds of each of the wheels needed to eliminate slip and wear problems,

d) precise determination of the actual orientation of each translation unit with respect to its ideal orientation and comparison with a limit offset angle.

e) if the actual orientation of any of the translation units with respect to their ideal orientation is superior at the limit lag, precise determination by the procedure of speed setpoint control to be transmitted to each wheel to position each of the translation units according to the proper orientation to start the runway advance,

e ') if the actual orientation of any of the translation units with respect to their ideal orientation is superior at the limit lag, precise determination by the procedure of speed setpoint control to be transmitted to each wheel to move the catwalk.

In this control procedure, the precise determination of the instantaneous position of the gateway and its characteristics are performed using additionally any of the following variables: position of the operator's command post with respect to the axis of the round, distance between the end of the cabin and round axis, position of the catwalk with respect to the Terminal facade, orientation of the cabin with respect to the axis of the gangway, column height with respect to the platform of the airport, cabin height relative to the platform of the airport, tilt of the runway with respect to the platform of the airport, and the projection on the platform of its length.

The procedure preferably defines the speed setpoint to be transmitted to each wheel when the actual orientation of any of the translation units with respect to its ideal orientation is greater than the limit offset as a linear combination of ideal speeds and correction of each wheel

The procedure can also define the speed setpoint to be transmitted to each wheel when the actual orientation of any of the translation units with respect to its ideal orientation is greater than the limit offset as a non-linear combination of ideal and correction speeds of each wheel

The operator is located in the cabin of the gateway and define the direction of the path to be followed by the gateway using any suitable means for it. At procedure you have the necessary means to control regardless of the speed of each wheel. The device of control is a programmable logic controller. The gateway has sensors and sensors needed to capture the variables required The length of the gateway can be calculated from the distance between the rolling system and the roundabout, from the distance traveled by the rolling system, or from of the extension of the telescopic tunnel structure.

The described procedure has a system redundant measurement of the actual position of each of the translation units capable of detecting any system failure main measurement, give the operator an alarm signal and allow the gateway to function properly in case of failure of the primary measurement system.

Brief description of the drawings

Figure 1 is a perspective view of a passenger boarding pass on airplanes equipped with a rolling device formed by two translation units.

Figure 2 shows a scheme of the gateway where its main parts are identified.

Figure 3 shows a top view of the gateway in which some variables used in the control procedure

Figure 4 is a view of the catwalk where show other variables used in the procedure of control.

Some variables are represented in Figure 5 calculated through the control procedure.

Figure 7 shows the units of translation and its positions.

Figures 6 and 8 show the logical diagrams of the operation of the procedure control.

Description a preferred embodiment

The invention is described as it applies to a conventional passenger boarding bridge on airplanes. Without However, it should be understood that the concepts described herein memory can also be applied to other types of systems passenger boarding

Figure 1 shows a conventional gateway with two translation units (2 and 3) where you can use the control procedure object of the invention. The gateway is formed by the roundabout (11), the column (16) that supports it, the tunnel (10) consisting of a telescopic structure, the cabin (8) which revolves around the round (14) located at the end of the tunnel (10), and the lifting system (17) supported by the device rolling (9).

Figure 2 shows a scheme of the gateway where its main parts are identified: the position of the panel operator control (1) in the cab (8), the device rolling (9) with the translation units (2 and 3) and their four wheels (4, 5, 6 and 7), the tunnel (10) formed by a structure telescopic, the round (14), and the roundabout (11) attached to the Terminal (13). At every moment of the trajectory the orientations of the two translation units are cut at one point (12).

To eliminate slip problems and wear of the wheels, at every moment of the maneuver the units translation (2, 3) of the rolling device (9) are positioned as indicated in figure 2 and its orientations define a point (12), called instantaneous center of rotation (CIR), whose position varies during the maneuver of the catwalk depending on the direction of the path defined by the operator and the length of the runway. The control procedure object of this invention is based on defining at every moment the position of this point (12) and define from this position the speeds of each of the wheels (4, 5, 6 and 7).

Other variables are represented in Figure 3 used in the control procedure (E, M, RA1, RA2, RB1, RB2, DA1, DA2, DB1, DB2, NA, NB, P, T; G, C, ZP and ZR). Some of these variables are fixed parameters of each execution, such as position of the elevation with respect to the axis of the round (M), position of the position operator control with respect to the axis of the round (P and T), distance between the end of the cabin and the axis of the round (C); position of each of the translation units with respect to the axis of the gangway (NA and NB), position of the wheels in each of the translation units with respect to the point of attachment to the structure of the elevation (RA1, RA2, RB1 and RB2), and diameter of each of the wheels (DA1, DA2, DB1 and DB2). There are other parameters that vary during the maneuver of the catwalk, such as the direction of the trajectory defined by the operator with respect to the axis of the gateway (ZP), whose value is defined with a joystick, a combination of push buttons or other system suitable for this purpose; the position of the gateway with respect to the Terminal (ZR), whose value is measured with a sensor or other system suitable for this purpose normally located in the roundabout or the column; the orientation of the cabin with respect to the axis of the gateway (G), whose value is measured with a sensor or other system suitable for this purpose normally located in the round or in the cabin; and the distance between the round axis and the roundabout axis (E), whose value is also a variable parameter, which is measured with a sensor or other system suitable for this purpose normally located in the tunnel.

Figure 4 shows three of the variables used in the system: column height relative to the airport platform (h), which is a fixed parameter for each execution; the cabin height with respect to the platform of the airport (H), which is a variable parameter during the maneuver of docking or undocking of the catwalk, whose value is measured in each instant with a sensor or other system suitable for this purpose located normally in the catwalk cabin; and the length of the runway measured from the axis of the roundabout-to the cab end (I), whose value is also a variable parameter, which is measured with a sensor or other system suitable for this purpose normally located in the tunnel or is calculated from the distance between the round axis and the roundabout axis (E) and the distance between the end of the cabin and the axis of the round (C). In function of these values you can know the inclination of the runway with respect to the airport platform (a) and the projection on the platform of its length (L).

From the variables represented in the Figures 3 and 4, the control procedure defines other parameters calculation, represented in figure 5, as the position of the CIR with respect to the center of the roundabout (s), the instantaneous radii of rotation of each of the translation units (DA and DB), their ideal orientations with respect to the axis of the catwalk (ZA and ZB), and the ideal speeds of each of the wheels (VA1 ', VA2', VB1 ', and VB2 ') necessary to eliminate slip problems and wear described above.

The logical diagram is represented in Figure 6 of the control procedure for the calculation of speeds ideal (VA1 ', VA2', VB1 'and VB2').

In each of the translation units places a measurement system that allows you to know precisely the angle formed by each translation unit with respect to a system of reference at any time during the maneuver of the catwalk, (ZA 'and ZB' in Figure 7).

Knowing the real orientation of each of the translation units with respect to the axis of the gateway (ZA 'and ZB '), the control procedure defines its position with respect to the ideal orientation (WA and WB).

If the walkway moves and the units of translation are not oriented according to their ideal orientation, there is sliding or wear of any of the system wheels. For avoid this problem, before starting the maneuver or whenever the operator defines a change in the direction of the trajectory of the gateway, it is necessary to place both translation units according to their ideal orientation (ZA and ZB).

To avoid continuous stops during maneuver the runway and perform the movement smoothly and continuous defines a limit value for the orientation offset of translation units (W), this value is defined so that if the walkway advances and any of its translation units is outdated (WA and WB) with respect to the ideal orientation (ZA and ZB) a value equal to or less than the defined limit value (W), the slip and wear that occurs on the wheels is negligible and does not cause problems in the operation of the runway. Only when the offset of any of the units of translation is greater than this value (W), the control procedure defines the speed setpoint that must be transmitted to each wheel to correct its position (VA1 '', VA2 '', VB1 '', and VB2 ''). If he offset of the two translation units is less than the value limit (W), the control procedure defines a setpoint of speed for each of the wheels (VA1, VA2, VB1, and VB2) that results from combining the ideal speeds, (VA1 ', VA2', VB1 ', and VB2 ') and correction (VA1' ', VA2' ', VB1' ', and VB2' ') of each wheel.

The logical diagram is represented in Figure 8 of the control procedure for the calculation of speeds (VA1, VA2, VB1, and VB2).

Claims (7)

1. Control procedure for rolling devices for boarding bridges formed by two translation units (2 and 3) characterized by comprising: a) receipt of the travel setpoint defined by the gateway operator (ZP), b) precise position determination snapshot of the gateway and its features through the uptake of all the necessary variables for this: position of the elevation relative to the axis of the round (M), distance between the axis round and the axis of roundabout at each instant (E) or the length of the runway measured from the center of the roundabout to the end of the cabin (I), position of each of the translation units with respect to the axis of the gangway (NA, NB), position of the wheels in each of the translation units with respect to the junction point with elevation structure (RA1, RA2, RB1, RB2), and diameter of each of the wheels (DA1, DA2, DB1 and DB2), c) determination of the calculation parameters: position of the instantaneous center of rotation (CIR) relative to the center of the roundabout (s), instantaneous turning radii of each of the translation units (DA, DB), ideal orientations regarding gateway axis (ZA and ZB), and ideal speeds of each of the wheels (VA1 ', VA2', VB1 ', and VB2'), d) precise determination of the actual orientation of each translation unit with respect to its ideal orientation (WA and WB) and comparison with a limit offset angle (W), e) if the actual orientation of any of the translation units with respect to their ideal orientation (WA and WB) is exceeding the limit offset (W), precise determination by the speed setpoint control procedure transmit to each wheel to position each of the units of translation according to the appropriate orientation to start the advance of the catwalk, e ') if the actual orientation of any of the translation units with respect to their ideal orientation (WA and WB) is exceeding the limit offset (W), precise determination by the speed setpoint control procedure transmit to each wheel to perform the displacement of the runway. 2. Control method according to claim 1, characterized in that the precise determination of the instantaneous position of the gangway and its characteristics is carried out additionally using any of the following variables: position of the operator's command post with respect to the axis of the round (P and T), distance between the end of the cabin and the round axis (C), position of the gangway with respect to the facade of the Terminal (ZR), orientation of the cabin with respect to the axis of the gangway (G), height of column with respect to the airport platform (h), cabin height with respect to the airport platform (H), inclination of the catwalk with respect to the airport platform (a), and the projection on the platform of its length (L) . 3. Control procedure according to previous claims, characterized in that it defines the speed setpoint to be transmitted to each wheel when the actual orientation of any of the translation units with respect to their ideal orientation (WA and WB) is greater than the limit offset (W) as a linear combination of the ideal (VA1 ', VA2', VB1 ', and VB2') and correction (VA1 '', VA2 '', VB1 '', and VB2 '') speeds of each wheel. 4. Control procedure according to claims 1 and 2, characterized in that it defines the speed setpoint that must be transmitted to each wheel when the actual orientation of any of the translation units with respect to its ideal orientation (WA and WB) is greater than the limit offset (W) as a non-linear combination of ideal speeds (VA1 ', VA2', VB1 ', and VB2') and correction (VA1 '', VA2 '', VB1 '', and VB2 '') of each wheel. 5. Control procedure according to previous claims, characterized in that it has the necessary means to independently control the speed of each wheel. 6. Control method according to previous claims, characterized in that the control device is a programmable logic controller. 7. Control procedure according to previous claims, characterized in that it has a redundant system for measuring the real position of each of the translation units (ZA 'and ZB') capable of detecting any failure of the main measurement system, giving a alarm signal to the operator and allow the correct operation of the gateway in case of failure of the primary measurement system.